Abstract
Mitochondrial superoxide flashes reflect a quantal, bursting mode of reactive oxygen species (ROS) production that arises from stochastic, transient opening of the mitochondrial permeability transition pore (mPTP) in many types of cells and in living animals. However, the regulatory mechanisms and the exact nature of the flash-coupled mPTP remain poorly understood. Here we demonstrate a profound synergistic effect between mitochondrial Ca(2+) uniport and elevated basal ROS production in triggering superoxide flashes in intact cells. Hyperosmotic stress potently augmented the flash activity while simultaneously elevating mitochondrial Ca(2+) and ROS. Blocking mitochondrial Ca(2+) transport by knockdown of MICU1 or MCU, newly identified components of the mitochondrial Ca(2+) uniporter, or scavenging mitochondrial basal ROS markedly diminished the flash response. More importantly, whereas elevating Ca(2+) or ROS production alone was inefficacious in triggering the flashes, concurrent physiological Ca(2+) and ROS elevation served as the most powerful flash activator, increasing the flash incidence by an order of magnitude. Functionally, superoxide flashes in response to hyperosmotic stress participated in the activation of JNK and p38. Thus, physiological levels of mitochondrial Ca(2+) and ROS synergistically regulate stochastic mPTP opening and quantal ROS production in intact cells, marking the flash as a coincidence detector of mitochondrial Ca(2+) and ROS signals.
Highlights
Superoxide flashes are newly discovered elemental mitochondrial reactive oxygen species (ROS) signaling events and reflect transient openings of mitochondrial permeability transition pore (mPTP)
Mitochondrial Ca2ϩ- and ROS-induced Activation of Superoxide Flashes—The present study has demonstrated that both the Ca2ϩ-induced flash activation (CIFA) mechanism and the ROS-induced flash activation (RIFA) mechanism regulate the stochastic gating of the mPTP and the resultant quantal ROS production in living cells at the single-mitochondrion level
Hyperactivity of mitochondrial superoxide flashes during hyperosmotic stress depends on the mitochondrial Ca2ϩ uniport and elevated basal ROS production
Summary
Superoxide flashes are newly discovered elemental mitochondrial ROS signaling events and reflect transient openings of mPTP. Physiological levels of mitochondrial Ca2؉ and ROS synergistically regulate stochastic mPTP opening and quantal ROS production in intact cells, marking the flash as a coincidence detector of mitochondrial Ca2؉ and ROS signals. TMPT-coupled superoxide flashes are thought to be local, elemental ROS signaling events They make only a miniscule contribution to global ROS in setting the overall redox status of the cell [18], but their incidence is regulated by an array of factors that converge on the mPTP and the electron transport chain complexes [20]. Our results showed a profound synergism between the physiological levels of mitochondrial Ca2ϩ and elevated ROS production in triggering superoxide flashes, revealing similarities and disparities between the two types of mPTPs in terms of their Ca2ϩ and ROS regulation
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